Neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the Ndufs4fky/fky mouse

Neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the Ndufs4fky/fky mouse

Mitochondrial dysfunction causes a range of early-onset neurological diseases and contributes to neurodegenerative conditions. The mechanisms of neurological damage however are poorly understood, as accessing relevant tissue from patients is difficult, and appropriate models are limited. Hence, we...

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Main Authors: Matthew J. Bird, Xiaonan W. Wijeyeratne, Jasper C. Komen, Adrienne Laskowski, Michael T. Ryan, David R. Thorburn, Ann E. Frazier
Format: Article
Language:English
Published: Portland Press, Biochemical Society 2014-11-01
Series:Bioscience Reports
Subjects:
metabolic stress
mitochondrial disease
mouse models
neuropathology
primary cells
reactive oxygen species
Online Access:http://www.bioscirep.org/bsr/034/e151/bsr034e151.htm
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spelling doaj-24a09d353dc54301b46476e31afb1d0c2020-11-24T21:06:14ZengPortland Press, Biochemical SocietyBioscience Reports1573-49352014-11-01346e0015110.1042/BSR20140151BSR20140151Neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the Ndufs4fky/fky mouseMatthew J. BirdXiaonan W. Wijeyeratne0Jasper C. Komen1Adrienne Laskowski2Michael T. Ryan3David R. ThorburnAnn E. Frazier Department of Biochemistry, La Trobe Institute for Molecular Science, La Trobe University, Bundoora, VIC 3086, Australia Murdoch Childrens Research Institute, Royal Children's Hospital, Parkville, VIC 3052, Australia Murdoch Childrens Research Institute, Royal Children's Hospital, Parkville, VIC 3052, Australia Department of Biochemistry, La Trobe Institute for Molecular Science, La Trobe University, Bundoora, VIC 3086, Australia Mitochondrial dysfunction causes a range of early-onset neurological diseases and contributes to neurodegenerative conditions. The mechanisms of neurological damage however are poorly understood, as accessing relevant tissue from patients is difficult, and appropriate models are limited. Hence, we assessed mitochondrial function in neurologically relevant primary cell lines from a CI (complex I) deficient Ndufs4 KO (knockout) mouse (Ndufs4fky/fky) modelling aspects of the mitochondrial disease LS (Leigh syndrome), as well as MEFs (mouse embryonic fibroblasts). Although CI structure and function were compromised in all Ndufs4fky/fky cell types, the mitochondrial membrane potential was selectively impaired in the MEFs, correlating with decreased CI-dependent ATP synthesis. In addition, increased ROS (reactive oxygen species) generation and altered sensitivity to cell death were only observed in Ndufs4fky/fky primary MEFs. In contrast, Ndufs4fky/fky primary isocortical neurons and primary isocortical astrocytes displayed only impaired ATP generation without mitochondrial membrane potential changes. Therefore the neurological dysfunction in the Ndufs4fky/fky mouse may partly originate from a more severe ATP depletion in neurons and astrocytes, even at the expense of maintaining the mitochondrial membrane potential. This may provide protection from cell death, but would ultimately compromise cell functionality in neurons and astrocytes. Furthermore, RET (reverse electron transfer) from complex II to CI appears more prominent in neurons than MEFs or astrocytes, and is attenuated in Ndufs4fky/fky cells.http://www.bioscirep.org/bsr/034/e151/bsr034e151.htmmetabolic stressmitochondrial diseasemouse modelsneuropathologyprimary cellsreactive oxygen species
collection DOAJ
language English
format Article
sources DOAJ
author Matthew J. Bird
Xiaonan W. Wijeyeratne
Jasper C. Komen
Adrienne Laskowski
Michael T. Ryan
David R. Thorburn
Ann E. Frazier
spellingShingle Matthew J. Bird
Xiaonan W. Wijeyeratne
Jasper C. Komen
Adrienne Laskowski
Michael T. Ryan
David R. Thorburn
Ann E. Frazier
Neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the Ndufs4fky/fky mouse
Bioscience Reports
metabolic stress
mitochondrial disease
mouse models
neuropathology
primary cells
reactive oxygen species
author_facet Matthew J. Bird
Xiaonan W. Wijeyeratne
Jasper C. Komen
Adrienne Laskowski
Michael T. Ryan
David R. Thorburn
Ann E. Frazier
author_sort Matthew J. Bird
title Neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the Ndufs4fky/fky mouse
title_short Neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the Ndufs4fky/fky mouse
title_full Neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the Ndufs4fky/fky mouse
title_fullStr Neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the Ndufs4fky/fky mouse
title_full_unstemmed Neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the Ndufs4fky/fky mouse
title_sort neuronal and astrocyte dysfunction diverges from embryonic fibroblasts in the ndufs4fky/fky mouse
publisher Portland Press, Biochemical Society
series Bioscience Reports
issn 1573-4935
publishDate 2014-11-01
description Mitochondrial dysfunction causes a range of early-onset neurological diseases and contributes to neurodegenerative conditions. The mechanisms of neurological damage however are poorly understood, as accessing relevant tissue from patients is difficult, and appropriate models are limited. Hence, we assessed mitochondrial function in neurologically relevant primary cell lines from a CI (complex I) deficient Ndufs4 KO (knockout) mouse (Ndufs4fky/fky) modelling aspects of the mitochondrial disease LS (Leigh syndrome), as well as MEFs (mouse embryonic fibroblasts). Although CI structure and function were compromised in all Ndufs4fky/fky cell types, the mitochondrial membrane potential was selectively impaired in the MEFs, correlating with decreased CI-dependent ATP synthesis. In addition, increased ROS (reactive oxygen species) generation and altered sensitivity to cell death were only observed in Ndufs4fky/fky primary MEFs. In contrast, Ndufs4fky/fky primary isocortical neurons and primary isocortical astrocytes displayed only impaired ATP generation without mitochondrial membrane potential changes. Therefore the neurological dysfunction in the Ndufs4fky/fky mouse may partly originate from a more severe ATP depletion in neurons and astrocytes, even at the expense of maintaining the mitochondrial membrane potential. This may provide protection from cell death, but would ultimately compromise cell functionality in neurons and astrocytes. Furthermore, RET (reverse electron transfer) from complex II to CI appears more prominent in neurons than MEFs or astrocytes, and is attenuated in Ndufs4fky/fky cells.
topic metabolic stress
mitochondrial disease
mouse models
neuropathology
primary cells
reactive oxygen species
url http://www.bioscirep.org/bsr/034/e151/bsr034e151.htm
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